RU2622749C2 - Method and device for manufacturing capsules - Google Patents

Abstract

FIELD: pharmacology.

SUBSTANCE: method of manufacturing the capsule 12 for storing the substance 14 includes providing the first part 2 of the capsule, characterized by the presence of the closed end 5 and the opposite open end 6, providing the second part 4 of the capsule, characterized by the presence of the closed end 7 and the opposite open end 8, partial filling the first part 2 of the capsule with the substance 14, supporting the outer side 43 of the first part 2 of the capsule and supporting the inner side 102 of the second part 4 of the capsule at the overlapping capsule areas when inserting the closed end 7 of the second part 4 of the capsule into the open end 6 of the first part 2 of the capsule until the areas of the capsule parts overlap with each other to thereby block the open end 6 of the first part 2 of the capsule and to form a chamber 104 within which the substance 14 is stored. The group of inventions also relates to a device for the manufacture of said capsules.

EFFECT: group of inventions prevents separation of capsule and eliminates deformation of the walls and open ends of the capsule.

24 cl, 10 dwg

Description

FIELD OF THE INVENTION

The present invention relates to a method and apparatus for manufacturing a capsule for storing a substance. In this document, the term "non-toxic gas" should be interpreted as any gas that, when ingested by a human or animal, is not toxic to them, and which, in particular, does not contain oxygen.

SUMMARY OF THE INVENTION

According to a first aspect of the present invention, there is provided a method of manufacturing a capsule for storing a substance, the method comprising the steps of:

providing the first part of the capsule of elastic material for storing the substance, while the first part of the capsule is characterized by the presence of a closed end and the opposite open end;

providing the second part of the capsule of elastic material, which is characterized by the presence of a closed end and the opposite open end;

at least partial filling with the substance of the first part of the capsule;

supporting at least part of the outer side of the first part of the capsule;

supporting at least part of the inner side of the second part of the capsule; and

the insert, while supporting the outer side of the first part of the capsule and the inner side of the second part of the capsule, the closed end of the second part of the capsule in the open end of the first part of the capsule until the areas of the parts of the capsule overlap with each other, thereby blocking the open end of the first parts of the capsule and form a chamber inside which the substance is stored.

The first part of the capsule may comprise a hollow cylindrical tubular body that defines an open end and a closed end, the closed end being domed.

The second part of the capsule may contain a hollow cylindrical tubular body that defines the open end and the closed end, while the closed end is dome-shaped.

The second part of the capsule may have a predetermined length limited between its ends, the specified length being less than the length limited between the ends of the first part of the capsule, the method comprising inserting the second part of the capsule into the first part of the capsule so that the second part of the capsule is completely inside the first parts of the capsule.

The method may include supporting the inner and outer sides of the overlapping regions of the first part of the capsule and the second part of the capsule.

The method may include connecting with each other the overlapping regions of the first part of the capsule and the second part of the capsule, thereby thereby sealing the chamber.

The method may include connecting the first part of the capsule and the second part of the capsule with each other while supporting said overlapping regions of the first and second parts of the capsule.

The method may include joining together the overlapping regions of the first part of the capsule and the second part of the capsule by heating and applying pressure to the first and second parts of the capsule so as to fuse the overlapping regions of the parts of the capsule with each other.

The method may include providing a gas-tight chamber in order to provide an adjustable gas environment inside the chamber, the method comprising arranging the first and second parts of the capsule inside the chamber and inserting the closed end of the second part of the capsule into the open end of the first part of the capsule when said parts are inside the chamber .

The method may include providing a non-toxic gas environment inside the chamber and inserting the closed end of the second capsule part into the first capsule part when said capsule parts are in a non-toxic gas environment.

The method may include creating a partial vacuum in the chamber, thereby reducing the gas pressure inside the chamber to below atmospheric pressure by inserting the closed end of the second part of the capsule into the open end of the first part of the capsule.

The method may include the following stages: providing a cap; at least partially filling the second part of the capsule with additional substance; and attaching the cap to one of the first part of the capsule and the second part of the capsule so as to limit the additional chamber inside which the additional substance is located.

The method may include attaching the cap to one of the first part of the capsule and the second part of the capsule so that the cap covers the open end of the second part of the capsule.

The first part of the capsule and the second part of the capsule can be made of digestible material, as a result of which the capsule can be digested in the human or animal body.

The first part of the capsule, the second part of the capsule and the cap can be made of digestible material, as a result of which the capsule can be digested in the human or animal body.

According to a second aspect of the present invention, there is provided a device for manufacturing a capsule for storing a substance, the device comprising:

means for supporting the first part of the capsule containing at least one structure for supporting the first part of the capsule, which is characterized by such dimensions and configuration as to provide support for at least a portion of the outer side of the first part of the capsule of elastic material intended to store substance therein wherein the first part of the capsule is characterized by the presence of a closed end and an opposite open end;

means for filling the capsule containing one or more nozzles for dispensing a substance, wherein the means for filling the capsule is intended to at least partially fill the first part of the capsule, which, when the device is functioning, is supported by a structure to support the first part of the capsule;

means for supporting the second part of the capsule containing at least one structure for supporting the second part of the capsule, which is characterized by such dimensions and configuration as to provide support for at least part of the inner side of the second part of the capsule of elastic material, and the second part of the capsule is characterized by the presence the closed end and the opposite open end, while the means for supporting the second part of the capsule is arranged to move between the following positions:

the first position, in which the structure for supporting the second part of the capsule, which is part of the means for supporting the second part of the capsule, is located at a distance from the structures for supporting the first part of the capsule included in the composition for supporting the first part of the capsule; and

the second position, in which the structure for supporting the second part of the capsule inserts the closed end of the second part of the capsule supported by it into the first part of the capsule supported by the structure for supporting the first part of the capsule, until the area of the second part of the capsule overlaps the area of the first part of the capsule thereby blocking the open end of the first part of the capsule so as to form an assembled capsule defining a chamber inside which the substance is stored.

The structure for supporting the first part of the capsule can be characterized by such dimensions and configuration that the first part of the capsule can be located in it by means of a tight fit by sliding.

The structure for supporting the first part of the capsule can be made in the form of a hollow structure in the form of a socket, which is characterized by such dimensions and shape to match the shape and dimensions of the outer side of the first part of the capsule.

The structure for supporting the second part of the capsule can be characterized by such dimensions and configuration that it can be inserted into the second part of the capsule by means of a snug fit.

The structure for supporting the second part of the capsule can be made in the form of a core structure, which is characterized by such dimensions and shape to match the shape and dimensions of the inner side of the second part of the capsule.

The device may include means for connecting parts of the capsule, designed to connect with each other the overlapping regions of the first part of the capsule and the second part of the capsule of each of the capsules in assembled form, thereby thereby sealing the chamber. The means for joining the parts of the capsule can be made in the form of at least one element for joining the parts of the capsule, intended for heating and applying pressure to the overlapping regions of the capsules in assembled form in order to connect the overlapping regions with each other.

The proposed device may contain a gas-tight chamber, inside which are the first and second parts of the capsule when inserting the second part of the capsule into the first part of the capsule in the process of forming the capsule in assembled form, thereby providing an adjustable gas environment inside the chamber.

The device may include a vacuum device to create a partial vacuum in the chamber in order to reduce the gas pressure inside the chamber to below atmospheric pressure.

Brief Description of the Figures

Further, with reference to the accompanying figures, additional features of the present invention are described using a non-limiting example of the present invention, while the accompanying figures show the following:

in FIG. 1 is a schematic sectional view of a capsule obtained according to a method for manufacturing a capsule in accordance with a first aspect of the present invention;

in FIG. 2 is a schematic cross-sectional view of another embodiment of a capsule obtained according to a capsule manufacturing method in accordance with a first aspect of the present invention;

in FIG. 3 is an exploded perspective view of a capsule manufacturing apparatus in accordance with a second aspect of the present invention;

in FIG. 4 is a perspective view of a capsule support tray included in the apparatus of FIG. 3;

in FIG. 5 is a local schematic sectional view of the capsule filling assembly of the device of FIG. 3;

in FIG. 6 is a local schematic cross-sectional view of the complete vacuum chamber and the partition insert assembly of the device of FIG. 3, while they are in a raised position;

In FIG. 7 is a local schematic cross-sectional view of the complete vacuum chamber and the partition insert assembly shown in FIG. 6, while they are in a raised position;

in FIG. 8 is a local schematic sectional view of the complete vacuum chamber and the partition insert assembly, which are shown in FIG.

6, while the casing of the vacuum chamber assembly is presented in the lowered position, and the node for inserting the partition is presented in the raised position;

in FIG. 9 shows a local schematic sectional view of a unit for connecting parts of the capsule included in the device of FIG. 3, wherein said assembly is presented in a raised position; and

in FIG. 10 shows a local, schematic sectional view of a unit for connecting parts of the capsule of FIG. 9, wherein said assembly is presented in a lowered position.

Detailed disclosure of the present invention

Consider FIG. 1 and 3-10, in which the device in accordance with the second aspect of the present invention is generally indicated by 10. The device 10 is configured to make the capsule 12 according to the method of manufacturing the capsule in accordance with the first aspect of the present invention.

Capsule 12 is a digestible hard gelatin capsule for storing a substance, such as, for example, Omega-3 oil 14, which, when placed in a capsule, must be stored in airtight isolation for two main reasons. Firstly, since Omega-3 oil 14 is in a fluid liquid state and therefore must be stored in a liquid-tight chamber inside the capsule. Secondly, since Omega-3 oil 14 is sensitive to degradation due to oxidation under the influence of oxygen in the atmosphere. In general, the capsule 12 comprises a first capsule part in the form of a capsule body 2 and a second part of the capsule in the form of a septum 4. The capsule body 2 is made of an elastic material based on gelatin and in the form of a hollow cylindrical tubular body that defines the closed end 5 and the opposite open end 6. The partition 4 is made of an elastic material based on gelatin and in the form of a hollow cylindrical tubular body that defines the closed end 7 and the opposite open end 8.

As shown in FIG. 3, in general, the device 10 comprises means for supporting the first part of the capsule, made in the form of several trays 16 for supporting the capsules; a capsule filling unit 20; complete vacuum chamber 22; means for supporting the second part of the capsule, made in the form of a node 24 for inserting the septum; and also a means for joining the parts of the capsule, made in the form of a node 28 for joining the parts of the capsule.

Consider FIG. 3 and 4, each tray 16 for supporting capsules contains an aluminum plate 30, which is characterized by the presence of forty-two hollow sockets 32, limited therein; peripheral rubber seal 34; and forty-two internal channels 36 that extend through the aluminum plate 30 from the lower end regions 38 of the aluminum plate 30 to the lowermost part of one of the sockets 32, and the purpose of which will be described in more detail below. Sockets 32 are located at equal distance from each other in the form of a grid consisting of six rows and seven columns. Each socket 32 is characterized by the proper size and configuration to support the outside 43 of the capsule body 2. More specifically, each nest 32 is characterized by such dimensions and shape as to fit the size and shape of the outer side 43 of the capsule body 2 so that the capsule body 2 can enter the nest 32 by means of a snug fit. More specifically, as shown in FIG. 5-10, the capsule body 2 is located in each socket 32 so that the socket 32 provides support to the outside 43 of the capsule body 2.

In use, each capsule support tray 16 is moved to different positions in the device of the invention that correspond to the different operating positions of the device 10. More specifically, when used, each capsule support tray 16 is sequentially moved between the capsule filling position in which the capsule support tray 16 is located under node 20 to fill the capsules; the position of the vacuum-insert, in which the tray 16 for supporting capsules is located under the chamber 22 of the vacuum assembly and the node 24 for inserting the partition; and the position of the connection of the parts of the capsule, in which the tray 16 for supporting capsules is located under the node 28 for connecting the parts of the capsule.

As shown in FIG. 3 and 5, the capsule filling assembly 20 comprises a movable capsule filling head 49 and a metering device 53. The capsule filling head 49 contains seven nozzles 52 that are equally spaced from each other and aligned in a row so that the position of each nozzle 52 corresponds to a specific socket 32 of an aluminum plate 30 located beneath it, as shown in FIG. 5. The rows of nozzles 52 are sequentially moved to the positions where the nozzles 52 are located above each row of sockets 32 of the aluminum plate 30. The metering device 53 is configured to direct a specific measured portion of Omega-3 oil 14 to each nozzle 52 to partially fill each capsule body 2 which is supported by the slots 32 of the tray 16 to support the capsules.

Consider FIG. 3 and 6-8, the vacuum chamber 22 assembly includes a casing 54 of the vacuum chamber; node 55 to move the casing of the vacuum chamber, designed to move the casing 54 of the vacuum chamber; a hole 58 for evacuation and a hole 60 for supplying nitrogen. The casing 54 of the vacuum chamber is characterized by the presence of a sealing structure 64, made on the lower peripheral edge; and a structure 62 in the form of a handle protruding from the casing 54, the purpose of which will be described in more detail below. The node 55 for moving the casing of the vacuum chamber contains a winch (not shown) with a steel cable 84, while a hook 86 is attached to the free end of the steel cable 84, connected to the structure 62 in the form of a handle of the casing 54. The node 55 for moving the casing of the vacuum chamber is arranged to move the casing 54 between the raised position, as shown in FIG. 3 and 6, and the lowered position, as shown in FIG. 7 and 8, wherein the sealing structure 64 of the casing 54 seals tightly with the rubber seal 34 of the capsule support tray 16 so as to limit the inner vacuum chamber 56, which is limited between the casing 54 and the capsule support tray 16. A hole 58 for evacuation is connected to a vacuum pump (not shown) so that during operation of the vacuum pump a partial vacuum is created inside the chamber 56 of the vacuum. The nitrogen supply opening 60 is connected to a nitrogen gas source for supplying nitrogen gas to the vacuum chamber 56.

Consider FIG. 3 and 6-8, a node 24 for inserting a partition is installed inside the casing 54 of the evacuation chamber 22, wherein said assembly contains forty-two rods 90 for inserting partitions and an installation 85 with a hydraulic drive for moving the rods, designed to move the rods 90 for insertion partitions. Each bar 90 for insertion of a partition is characterized by a threaded end (not shown); the opposite end, which is connected to the core 88; and a hollow inner channel 91 extending from the threaded end of the rod 90 to its opposite end. Each core 88 is characterized by the presence of a hollow central channel 89 passing through it, with each core configured to hold the septum 4. More specifically, each core 88 is dimensioned and configured so that it can be inserted through the open end 8 of the septum 4 so that to enter the partition 4 by means of a tight fit by sliding. More specifically, each rod 88 is dimensioned to fit the shape and dimensions of the inner side 102 of the partition 4. The rod-moving apparatus 85 comprises four guide racks 107; a mounting plate 103; forty-two springs 105 and nuts 92; a drive plate 106 and a hydraulic drive 108; and a movable piston 101. The upper ends of the guide racks 107 are attached to the casing 54 of the vacuum chamber 22 assembly. The mounting plate 103 is slidably mounted on the guide posts 107 and is characterized by forty-two evenly spaced openings that extend through the plate and in which the rods 90 for inserting the partitions are located. Each spring 105 is located on one of the partitions rods 90, with nuts 92 screwed onto the threaded ends of the partitions rods 90, as shown in FIG. 6-8. The hydraulic actuator 108 is arranged to move the piston 101 to displace the mounting plate 103 and the rods 90 mounted thereon for inserting partitions for reasons that will be described in more detail below.

In use, the assembly 55 for moving the casing of the vacuum chamber moves the casing 54 to the lowered position, as shown in FIG. 7 and 8, wherein the sealing structure 64 of the casing 54 seals tightly with the rubber seal 34 of the tray 16 to support the capsules. A vacuum pump is activated to extract air from the vacuum chamber 56 in order to create a partial vacuum inside the vacuum chamber 56 so as to reduce the internal pressure in the vacuum chamber 56 to a value of 10 kPa to 70 kPa. Then, nitrogen gas is introduced into the vacuum chamber 56 through the nitrogen supply opening 60 in order to increase the internal pressure inside the vacuum chamber 56 to a value of from 20 kPa to 90 kPa, which is significantly lower than atmospheric pressure for reasons that will be described in more detail below.

In use, the rod transferring device 85 displaces the piston 101 in order to move the rod 90 for inserting partitions and cores 88 between the first position, as shown in FIG. 6, in which the cores 88 are located at some distance from the sockets 32 of the trays 16 for supporting the capsules, and the second position shown in FIG. 7, in which the cores 88 insert the closed end 7 of each partition 4 held by them inside one of the capsule bodies 2, supported by sockets 32 trays 16 for supporting capsules, until the area of each partition 4 overlaps the area of one of the capsule bodies 2, thereby blocking the open ends 6 of the capsule body 2 and, as a result, form PSUL 12 assembled, define a chamber 104, which stores the oil 14 Omega-3.

It should be borne in mind that the sockets 32 and cores 88 jointly support the inner and outer sides of the overlapping region of the capsule body 2 and the partition 4, as shown in FIG. 7, during insertion of the closed end 7 of the septum 4 into the open end 6 of the capsule body 2. Providing support to the outside of the capsule body 2 and the inside of the septum 4 is preferable during insertion, since said support prevents warping and / or changing the shape of the open ends 6, 8 of the capsule body 2 and the septum 4 when inserting the closed end 7 of the septum 4 into the inside of the case 2 capsules. In this regard, it should be understood that gelatin capsules are extremely fragile and easily deformable and / or destructible when relatively small forces are applied to them. Any deformation of the shape of the capsule body 2 will also prevent the capsule body 2 from being removed from the socket 32. In addition, the Applicant has found that providing support for the septum 4 and the outside of the capsule body 2 allows for smooth movement of the septum 4 relative to the capsule body 2 when inserting the closed end 7 septa 4 into the open end 6 of the housing 2 of the capsule.

Consider FIG. 3, 9 and 10, the assembly 28 for joining the capsule parts comprises a head 118 for joining the capsule parts; a support structure 120 for supporting the head 118 for connecting parts of the capsules; and hydraulic drive 122 heating cores. The head 118 for connecting the parts of the capsules is characterized by the presence of forty-two heating cores 124 mounted on the lower ends of the rods 126, which protrude from the lower surface of the head 118 for connecting the parts of the capsules, as shown in FIG. 9 and 10. Heating cores 124 are spaced from each other at a predetermined distance. More specifically, the distance between the heating cores 124 corresponds to the distance between the slots 32 of the aluminum plate 30 of the trays 16 for supporting the capsules. More specifically, as shown in FIG. 9 and 10, each heating core 124 is located above one of the slots 32 of the tray 16 to support the capsules. The hydraulic drive 122 of the heating cores is arranged to move the heating cores 124 between the raised position, as shown in FIG. 9, in which each heating core 124 is located at a distance from the capsule support tray 16, and a lowered position in which each heating core 124 is inserted into the open end 7 of the partition 4, as shown in FIG. 10.

In use, each heating core 124 is heated to a temperature of from 100 ° C to 120 ° C (optimally 110 ° C) and is applied to the partition 4 for about five to ten seconds, as shown in FIG. 10. Furthermore, in use, the heating core 124 supports, shapes, and welds to each other the overlapping portions of the capsule body 2 and the baffle 4 so as to form a fused wall region 109 of the overlapping portions, as shown in FIG. 10. The fused wall region 109 of the overlapping parts includes from 0.8 mm to 1.5 mm of the overlapping parts of the capsule body 2 and the partition 4 which are welded together.

It should be borne in mind that the inner and outer sides of the capsule body 2 and the partition 4 are supported by the sockets 32 and heating cores 124 in the process of connecting the overlapping parts of the partition 4 and the capsule body 2, as shown in FIG. 10. More specifically, as shown in FIG. 10, when the capsule body 2 and the partition 4 are welded to each other, the heating cores 124 and the sockets 32 jointly support the inner and outer sides of the overlapping parts of the capsule body 2 and the partition 4. The applicant believes that the internal and external sides of the capsule body 2 and the septum support 4 in the process of connecting the capsule body 2 and the partition 4 to each other 4 is also preferable in order to ensure proper and optimal alignment and orientation of the capsule body 2 and the partition 4 relative to each other. The Applicant has found that the support described herein provides proper molding and tight closure of the capsule 12. In addition, the Applicant notes that the support of the capsule body 12 and the partition 4 during the connection limits the possibility of deformation and / or collapse of the capsule body 2 and the partition 4 in the process of connecting.

In addition, it should also be understood that during operation, gaseous nitrogen supplied to the chamber 104 reduces the atmospheric oxygen concentration inside the chamber 104 and thereby reduces the oxidation state of the 14 Omega-3 oil. In addition, as a result of providing gas pressure values lower than atmospheric in chamber 104, there is a significant reduction in the likelihood of Omega-3 oil 14 escaping from chamber 104. Additionally, Applicant has found that lowering gas pressure inside chamber 104 to below atmospheric pressure is extremely preferred during connecting with each other overlapping areas of the septum and capsule body. In this regard, the Applicant has discovered that during the connection process, the core 124 also heats the Omega-3 oil 14 in the chamber 104, which leads to its expansion. As a result of this expansion, there is an increase in pressure inside the chamber 104. In order to overcome this problem, the internal pressure inside the chamber 104 is reduced to a pressure that is sufficiently lower than atmospheric pressure, as a result of which, when heating and applying pressure during the connection, the internal pressure in chamber 104 remains below atmospheric pressure, in particular, after the expansion of Omega-3 oil 14 due to heating of the septum and capsule body. This ensures that the internal pressure in the chamber 104 will be approximately equal to or lower than atmospheric pressure after the capsule parts are joined, which, in turn, ensures the preservation of an effective tight seal, since the pressure in the chamber 104 does not rise above atmospheric pressure. Thus, this decrease in pressure inside the chamber 104 is advantageous, since increased internal pressure inside the chamber 104 is undesirable, since it can adversely affect the hermetic seal of the chamber 104. In addition, the Applicant has found that reducing the gas pressure in the chamber 104 to a pressure lower atmospheric is also preferred after the connection process. More specifically, Applicant has found that people taking capsules 12 often store these capsules 12 under conditions with relatively high temperatures, for example, in their cars in which the ambient temperature is elevated. The Applicant has found that lowering the gas pressure in the chamber 104 in the manufacture of the capsule to below atmospheric pressure, in particular, makes it possible to use the capsules at relatively high temperatures, which can increase the pressure in the chamber 104. As a result, when the ambient temperature the capsules 12, to relatively high levels, the capsule body 2 and the baffle 4 will not be affected by the internal pressure in the chamber 104, the values of which exceed atmospheric pressure. In this regard, it should be borne in mind that when the value of the internal pressure of the chamber 104 exceeds the value of atmospheric pressure for a long period of time, there is a rather high probability that a violation of the hermetic seal of the capsule may occur.

The device 10 further comprises a vacuum tray system for supporting (not shown) and a vacuum rod system for inserting partitions (not shown). The support tray vacuum system is configured to create partial vacuum in the inner channel 36 of the capsule support tray 16 so as to ensure that the capsule bodies 2 are held inside the sockets 32 by creating a vacuum at the lower end of the sockets 32 when the cores 88 and heating cores 124 are removed from the partitions 4 during the operation of the device. The vacuum system of rods for inserting partitions is configured to create a partial vacuum in the inner channel 91 of the rods 90 for inserting the partitions and the inner channel 89 of the cores 88 in such a way as to hold the partitions 4 on each core 88 by creating a vacuum at the lower end of each core 88 in the process device functioning.

The applicant notes that the capsule 12 can be used in specific practical applications, according to which the capsule must necessarily contain an additional substance, such as, for example, medicine 130, which should be stored separately from Omega-3 oil 14 stored in the chamber 104. More specifically, the septum 4 of the capsule 12 is filled with drug 130 and the capsule 12 is closed with a cap, as shown in FIG. 3 using a standard caps closure and capsule filling machine, which is used to close standard capsule bodies using standard caps 132 to form the capsule 134 of FIG. 2, wherein each capsule 134 is characterized by the presence of an additional chamber 136, within which the drug 130 is located. Alternatively, the Applicant notes that in some cases the capsules 12 and caps 132 will be delivered to the applicant’s client, thereby allowing the indicated client of the applicant to fill the additional chamber 136 with the desired substance and cap closure of the capsule 12 using a standard machine for closing caps and filling capsules owned by the client.

In addition, it should be understood that maintaining the shape and / or size of the open ends 6, 8 of the capsule body 2 and the partition 4 is extremely important when connecting the capsule body 2 and the partition 4 to each other, in particular in order to ensure a tight fit of the cap 132, as shown in FIG. 2. In addition, the above-described method of supporting the capsule body 2 and the septum 4 is very important to ensure that the shape and size of the capsule 12 is maintained so that it can pass through standard machines to close the caps and fill the capsules, which, due to their inherent high speed and accuracy in the process of functioning, can only process capsules, characterized by accurate and uniform shapes and sizes.

The applicant notes that the digestible capsule 134 is advantageous for storing two substances, such as Omega-3 oil 14 and drug 130, which preferably should be stored separately from each other in separate chambers. In fact, other substances than Omega-3 oil 14 and drug 130 can be stored in chamber 104 and additional chamber 136. In addition, the Applicant notes that capsule 134 is well suited for storing a liquid and dry composition, while the liquid composition is in a liquid state and, therefore, should be stored in a sealed chamber in order to prevent leakage of liquid from the specified chamber. Applicant notes that capsule 134 is also preferred for storing two compositions that must be stored separately from each other in order to prevent decomposition and / or reaction and / or contamination of one or both of the compositions. In particular, the Applicant notes that capsule 134 is advantageous for storing the pharmacological composition in one of the chambers 104, 136 and the natural composition in the other of the chambers 104, 136.

It should be borne in mind that the specific configuration of the device 10 used in accordance with the method according to the present invention can be significantly changed, while it will still include the essential features of the method according to the present invention, as described above. In addition, the device 10 may implement a method different from the method according to the present invention, and similarly, the method according to the present invention can be implemented by a device different from the device 10 described above.

Applicant notes that capsule body 2, septum 4, and cap 132 are molded in accordance with known manufacturing procedures for forming hard gelatin capsules.

In addition, the Applicant notes that the device 10 and the method according to the present invention can be used to make other types of capsules, other than the digestible capsules 12 and 134 described above in this document. More specifically, the Applicant notes that using the specified method and / or the specified device can be made capsule (not shown), which is configured to store compositions consisting of two parts that must be stored separately from each other, such as, for example, highly reactive or explosive substances or, alternatively, two-component adhesives.

According to another embodiment of the present invention (not shown), the device comprises a joint assembly for inserting the septum and joining the capsule parts, which replaces the septum inserting assembly 24 and the assembly 28 for joining the capsule parts. A joint unit for inserting the septum and connecting parts of the capsule (not shown) is located in the vacuum chamber 56. As a result of this, the above-described insertion of the septum 4 into the capsule body 2, as well as the above-described connection of the capsule body 2 and the septum 4 with each other, are carried out in a controlled gas environment of the vacuum chamber 56.

Claims (33)

1. A method of manufacturing a capsule for storing a substance, the method includes the steps of: providing the first part of the capsule of elastic material for storing the substance, while the first part of the capsule is characterized by the presence of a closed end and the opposite open end; providing the second part of the capsule of elastic material, which is characterized by the presence of a closed end and the opposite open end; at least partial filling with the substance of the first part of the capsule; and inserting the closed end of the second part of the capsule into the open end of the first part of the capsule until the areas of the parts of the capsule overlap with each other, thereby blocking the open end of the first part of the capsule and forming a chamber inside which the substance is stored, characterized in that the method includes supporting at least part of the outer side of the first part of the capsule and supporting at least part of the inner side of the second part of the capsule in overlapping regions of the parts of the capsule by inserting the closed end of the second part of the capsule into the open end of the first part of the capsule. 2. The method according to p. 1, characterized in that the first part of the capsule contains a hollow cylindrical tubular body that defines the open end and the closed end, while the closed end is dome-shaped. 3. The method according to p. 1, characterized in that the second part of the capsule contains a hollow cylindrical tubular body that defines the open end and the closed end, while the closed end is characterized by a domed shape. 4. The method according to p. 1, characterized in that the second part of the capsule is characterized by a predetermined length limited between its ends, the specified length being less than the length limited between the ends of the first part of the capsule, the method comprising inserting the second part of the capsule into the first part of the capsule such a distance that the second part of the capsule is located completely inside the first part of the capsule. 5. The method according to p. 1, characterized in that the method involves connecting with each other the overlapping areas of the first part of the capsule and the second part of the capsule, thereby ensuring a tight seal of the chamber. 6. The method according to p. 5, characterized in that the first part of the capsule is connected to the second part of the capsule while supporting said overlapping regions of the first and second parts of the capsule. 7. The method according to p. 5, characterized in that the overlapping areas of the first part of the capsule and the second part of the capsule are connected to each other by heating and applying pressure to the first and second parts of the capsule so as to fuse with each other the overlapping areas of the parts of the capsule. 8. The method according to p. 1, characterized in that the method provides for a gas-tight chamber in order to provide an adjustable gas environment inside the chamber, the method comprising arranging the first and second parts of the capsule inside the chamber and inserting the closed end of the second part of the capsule into the open the end of the first part of the capsule when these parts are inside the chamber. 9. The method according to p. 8, characterized in that the method provides for providing a non-toxic gas medium inside the chamber and inserting the closed end of the second part of the capsule into the first part of the capsule, when these parts of the capsule are in the environment of non-toxic gas. 10. The method according to p. 8, characterized in that a partial vacuum is created in the chamber, thereby reducing the gas pressure inside the chamber to below atmospheric pressure when inserting the closed end of the second part of the capsule into the open end of the first part of the capsule. 11. The method according to any one of paragraphs. 1-10, characterized in that the method comprises the following stages: providing a cap; at least partially filling the second part of the capsule with additional substance; and attaching the cap to one of the first part of the capsule and the second part of the capsule so as to limit the additional chamber inside which the additional substance is located. 12. The method according to p. 11, characterized in that the method involves attaching the cap to one of the first part of the capsule and the second part of the capsule so that the cap covers the open end of the second part of the capsule. 13. The method according to p. 1, characterized in that the first and second parts of the capsule are made of digestible material, as a result of which the capsule can be digested. 14. The method according to p. 13, characterized in that the first part of the capsule, the second part of the capsule and the cap are made of digestible material, as a result of which the capsule can be digested. 15. A device for manufacturing a capsule for storing a substance, the device includes: means for supporting the first part of the capsule, containing at least one structure for supporting the first part of the capsule, in order to provide support for the first part of the capsule of elastic material intended for storing substance therein, wherein the first part of the capsule is characterized by the presence of a closed end and an opposite open end; means for filling the capsule, comprising one or more nozzles for dispensing a substance, wherein the means for filling the capsule is intended to at least partially fill the first part of the capsule, which, when the device is functioning, is supported by a structure to support the first part of the capsule; and means for supporting the second part of the capsule, comprising at least one structure for supporting the second part of the capsule, to provide support for the second part of the capsule of elastic material, the second part of the capsule is characterized by the presence of a closed end and an opposite open end, while the means for supporting the second part of the capsule made with the ability to move between: the first position, in which the structure for supporting the second part of the capsule, which is part of the means for supporting the second part of the capsule, is located at a distance from the structures for supporting the first part of the capsule included in the composition for supporting the first part of the capsule; and the second position in which the structure for supporting the second part of the capsule inserts the closed end of the second part of the capsule supported by it into the first part of the capsule supported by the structure for supporting the first part of the capsule, until the region of the second part of the capsule overlaps the region of the first part of the capsule, thereby blocking the open end of the first part of the capsule so as to form an assembled capsule defining a chamber within which a substance is stored, characterized in that the structure for The arms of the first part of the capsule of the means for supporting the first part of the capsule are characterized by such dimensions and configuration as to provide support for at least part of the outer side of the first part of the capsule in the overlapping regions of the parts of the capsule, and the structure for supporting the second part of the capsule of the means for supporting the second part of the capsule such dimensions and configuration to provide support for at least a portion of the inner side of the second part of the capsule in overlapping regions of the parts of the capsule. 16. The device according to p. 15, characterized in that the structure for supporting the first part of the capsule is characterized by such dimensions and configuration that the first part of the capsule can be located in it by means of a tight fit by sliding. 17. The device according to p. 16, characterized in that the structure for supporting the first part of the capsule is characterized by such dimensions and configuration that the first part of the capsule can be located in it by means of a tight fit by sliding, and in which the structure for supporting the first part of the capsule is made in the form hollow design in the form of a nest, which is characterized by such dimensions and shape to match the shape and dimensions of the outer side of the first part of the capsule. 18. The device according to p. 15, characterized in that the structure for supporting the second part of the capsule is characterized by such dimensions and configuration that it can be inserted into the second part of the capsule by means of a tight fit by sliding. 19. The device according to p. 18, characterized in that the structure for supporting the first part of the capsule is characterized by such dimensions and configuration that the first part of the capsule can be located in it by means of a tight fit by sliding, and in which the structure for supporting the second part of the capsule is made in the form a core-like structure, which is characterized by such dimensions and shape to match the shape and dimensions of the inner side of the second part of the capsule. 20. The device according to p. 15, characterized in that the device includes means for connecting parts of the capsule, designed to connect with each other the overlapping regions of the first part of the capsule and the second part of the capsule of each capsule in assembled form, thereby ensuring a tight seal of the chamber. 21. The device according to p. 20, characterized in that the means for connecting the parts of the capsule is made in the form of at least one element for connecting parts of the capsule, intended for heating and applying pressure to the overlapping regions of the capsules in assembled form in order to connect each other with other overlapping areas. 22. The device according to p. 21, characterized in that the structure for supporting the first part of the capsule and the structure for supporting the second part of the capsule together support the inner and outer sides of the overlapping regions of the first and second parts of the capsules, respectively, during insertion of the closed end of the second part of the capsule into the open end the first part of the capsule. 23. The device according to any one of paragraphs. 16-22, characterized in that the said device comprises a gas-tight chamber, inside of which there are first and second parts of the capsule when the second part of the capsule is inserted into the first part of the capsule during the formation of the capsule in assembled form, thereby providing an adjustable gas environment inside the chamber. 24. The device according to p. 23, characterized in that the said device comprises a vacuum device for creating a partial vacuum in the chamber in order to reduce the gas pressure inside the chamber to below atmospheric pressure.

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